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version 1.10, 2003/12/08 00:55:31
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version 1.30, 2005/03/18 06:49:16
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| #include "compiler.h" |
#include "compiler.h" |
| |
|
| |
#ifndef NP2_MEMORY_ASM |
| |
|
| #include "cpucore.h" |
#include "cpucore.h" |
| #include "memory.h" |
|
| #include "egcmem.h" |
|
| #include "pccore.h" |
#include "pccore.h" |
| #include "iocore.h" |
#include "iocore.h" |
| |
#include "memtram.h" |
| |
#include "memvram.h" |
| |
#include "memegc.h" |
| |
#if defined(SUPPORT_PC9821) |
| |
#include "memvga.h" |
| |
#endif |
| |
#include "memems.h" |
| |
#include "memepp.h" |
| #include "vram.h" |
#include "vram.h" |
| #include "font.h" |
#include "font.h" |
| |
|
| |
|
| #define USE_HIMEM |
UINT8 mem[0x200000]; |
| #if defined(TRACE) |
|
| #define MEMORY_DEBUG |
|
| #endif |
|
| |
|
| // ---- write byte |
|
| |
|
| static void MEMCALL i286_wt(UINT32 address, REG8 value) { |
|
| |
|
| mem[address & CPU_ADRSMASK] = (BYTE)value; |
typedef void (MEMCALL * MEM8WRITE)(UINT32 address, REG8 value); |
| } |
typedef REG8 (MEMCALL * MEM8READ)(UINT32 address); |
| |
typedef void (MEMCALL * MEM16WRITE)(UINT32 address, REG16 value); |
| static void MEMCALL tram_wt(UINT32 address, REG8 value) { |
typedef REG16 (MEMCALL * MEM16READ)(UINT32 address); |
| |
|
| CPU_REMCLOCK -= vramop.tramwait; |
|
| if (address < 0xa2000) { |
|
| mem[address] = (BYTE)value; |
|
| tramupdate[LOW12(address >> 1)] = 1; |
|
| gdcs.textdisp |= 1; |
|
| } |
|
| else if (address < 0xa3fe0) { |
|
| if (!(address & 1)) { |
|
| mem[address] = (BYTE)value; |
|
| tramupdate[LOW12(address >> 1)] = 1; |
|
| gdcs.textdisp |= 1; |
|
| } |
|
| } |
|
| else if (address < 0xa4000) { |
|
| if (!(address & 1)) { |
|
| if ((!(address & 2)) || (gdcs.msw_accessable)) { |
|
| mem[address] = (BYTE)value; |
|
| tramupdate[LOW12(address >> 1)] = 1; |
|
| gdcs.textdisp |= 1; |
|
| } |
|
| } |
|
| } |
|
| else if (address < 0xa5000) { |
|
| if ((address & 1) && (cgwindow.writable & 1)) { |
|
| cgwindow.writable |= 0x80; |
|
| fontrom[cgwindow.high + ((address >> 1) & 0x0f)] = (BYTE)value; |
|
| } |
|
| } |
|
| } |
|
| |
|
| static void MEMCALL vram_w0(UINT32 address, REG8 value) { |
|
| |
|
| CPU_REMCLOCK -= vramop.vramwait; |
// ---- MAIN |
| mem[address] = (BYTE)value; |
|
| vramupdate[LOW15(address)] |= 1; |
|
| gdcs.grphdisp |= 1; |
|
| } |
|
| |
|
| static void MEMCALL vram_w1(UINT32 address, REG8 value) { |
static REG8 MEMCALL memmain_rd8(UINT32 address) { |
| |
|
| CPU_REMCLOCK -= vramop.vramwait; |
return(mem[address]); |
| mem[address + VRAM_STEP] = (BYTE)value; |
|
| vramupdate[LOW15(address)] |= 2; |
|
| gdcs.grphdisp |= 2; |
|
| } |
} |
| |
|
| static void MEMCALL grcg_rmw0(UINT32 address, REG8 value) { |
static REG16 MEMCALL memmain_rd16(UINT32 address) { |
| |
|
| REG8 mask; |
const UINT8 *ptr; |
| BYTE *vram; |
|
| |
|
| CPU_REMCLOCK -= vramop.grcgwait; |
ptr = mem + address; |
| mask = ~value; |
return(LOADINTELWORD(ptr)); |
| address = LOW15(address); |
|
| vramupdate[address] |= 1; |
|
| gdcs.grphdisp |= 1; |
|
| vram = mem + address; |
|
| if (!(grcg.modereg & 1)) { |
|
| vram[VRAM0_B] &= mask; |
|
| vram[VRAM0_B] |= (value & grcg.tile[0].b[0]); |
|
| } |
|
| if (!(grcg.modereg & 2)) { |
|
| vram[VRAM0_R] &= mask; |
|
| vram[VRAM0_R] |= (value & grcg.tile[1].b[0]); |
|
| } |
|
| if (!(grcg.modereg & 4)) { |
|
| vram[VRAM0_G] &= mask; |
|
| vram[VRAM0_G] |= (value & grcg.tile[2].b[0]); |
|
| } |
|
| if (!(grcg.modereg & 8)) { |
|
| vram[VRAM0_E] &= mask; |
|
| vram[VRAM0_E] |= (value & grcg.tile[3].b[0]); |
|
| } |
|
| } |
} |
| |
|
| static void MEMCALL grcg_rmw1(UINT32 address, REG8 value) { |
static void MEMCALL memmain_wr8(UINT32 address, REG8 value) { |
| |
|
| REG8 mask; |
mem[address] = (UINT8)value; |
| BYTE *vram; |
|
| |
|
| CPU_REMCLOCK -= vramop.grcgwait; |
|
| mask = ~value; |
|
| address = LOW15(address); |
|
| vramupdate[address] |= 2; |
|
| gdcs.grphdisp |= 2; |
|
| vram = mem + address; |
|
| if (!(grcg.modereg & 1)) { |
|
| vram[VRAM1_B] &= mask; |
|
| vram[VRAM1_B] |= (value & grcg.tile[0].b[0]); |
|
| } |
|
| if (!(grcg.modereg & 2)) { |
|
| vram[VRAM1_R] &= mask; |
|
| vram[VRAM1_R] |= (value & grcg.tile[1].b[0]); |
|
| } |
|
| if (!(grcg.modereg & 4)) { |
|
| vram[VRAM1_G] &= mask; |
|
| vram[VRAM1_G] |= (value & grcg.tile[2].b[0]); |
|
| } |
|
| if (!(grcg.modereg & 8)) { |
|
| vram[VRAM1_E] &= mask; |
|
| vram[VRAM1_E] |= (value & grcg.tile[3].b[0]); |
|
| } |
|
| } |
} |
| |
|
| static void MEMCALL grcg_tdw0(UINT32 address, REG8 value) { |
static void MEMCALL memmain_wr16(UINT32 address, REG16 value) { |
| |
|
| BYTE *vram; |
UINT8 *ptr; |
| |
|
| CPU_REMCLOCK -= vramop.grcgwait; |
ptr = mem + address; |
| address = LOW15(address); |
STOREINTELWORD(ptr, value); |
| vramupdate[address] |= 1; |
|
| gdcs.grphdisp |= 1; |
|
| vram = mem + address; |
|
| if (!(grcg.modereg & 1)) { |
|
| vram[VRAM0_B] = grcg.tile[0].b[0]; |
|
| } |
|
| if (!(grcg.modereg & 2)) { |
|
| vram[VRAM0_R] = grcg.tile[1].b[0]; |
|
| } |
|
| if (!(grcg.modereg & 4)) { |
|
| vram[VRAM0_G] = grcg.tile[2].b[0]; |
|
| } |
|
| if (!(grcg.modereg & 8)) { |
|
| vram[VRAM0_E] = grcg.tile[3].b[0]; |
|
| } |
|
| (void)value; |
|
| } |
} |
| |
|
| static void MEMCALL grcg_tdw1(UINT32 address, REG8 value) { |
|
| |
|
| BYTE *vram; |
// ---- N/C |
| |
|
| CPU_REMCLOCK -= vramop.grcgwait; |
static REG8 MEMCALL memnc_rd8(UINT32 address) { |
| address = LOW15(address); |
|
| vramupdate[address] |= 2; |
|
| gdcs.grphdisp |= 2; |
|
| vram = mem + address; |
|
| if (!(grcg.modereg & 1)) { |
|
| vram[VRAM1_B] = grcg.tile[0].b[0]; |
|
| } |
|
| if (!(grcg.modereg & 2)) { |
|
| vram[VRAM1_R] = grcg.tile[1].b[0]; |
|
| } |
|
| if (!(grcg.modereg & 4)) { |
|
| vram[VRAM1_G] = grcg.tile[2].b[0]; |
|
| } |
|
| if (!(grcg.modereg & 8)) { |
|
| vram[VRAM1_E] = grcg.tile[3].b[0]; |
|
| } |
|
| (void)value; |
|
| } |
|
| |
|
| static void MEMCALL egc_wt(UINT32 address, REG8 value) { |
(void)address; |
| |
return(0xff); |
| egc_write(address, value); |
|
| } |
} |
| |
|
| static void MEMCALL emmc_wt(UINT32 address, REG8 value) { |
static REG16 MEMCALL memnc_rd16(UINT32 address) { |
| |
|
| extmem.pageptr[(address >> 14) & 3][LOW14(address)] = (BYTE)value; |
(void)address; |
| |
return(0xffff); |
| } |
} |
| |
|
| static void MEMCALL i286_wn(UINT32 address, REG8 value) { |
static void MEMCALL memnc_wr8(UINT32 address, REG8 value) { |
| |
|
| (void)address; |
(void)address; |
| (void)value; |
(void)value; |
| } |
} |
| |
|
| |
static void MEMCALL memnc_wr16(UINT32 address, REG16 value) { |
| |
|
| // ---- read byte |
(void)address; |
| |
(void)value; |
| static REG8 MEMCALL i286_rd(UINT32 address) { |
|
| |
|
| return(mem[address & CPU_ADRSMASK]); |
|
| } |
|
| |
|
| static REG8 MEMCALL tram_rd(UINT32 address) { |
|
| |
|
| CPU_REMCLOCK -= vramop.tramwait; |
|
| if (address < 0xa4000) { |
|
| return(mem[address]); |
|
| } |
|
| else if (address < 0xa5000) { |
|
| if (address & 1) { |
|
| return(fontrom[cgwindow.high + ((address >> 1) & 0x0f)]); |
|
| } |
|
| else { |
|
| return(fontrom[cgwindow.low + ((address >> 1) & 0x0f)]); |
|
| } |
|
| } |
|
| return(mem[address]); |
|
| } |
|
| |
|
| static REG8 MEMCALL vram_r0(UINT32 address) { |
|
| |
|
| CPU_REMCLOCK -= vramop.vramwait; |
|
| return(mem[address]); |
|
| } |
|
| |
|
| static REG8 MEMCALL vram_r1(UINT32 address) { |
|
| |
|
| CPU_REMCLOCK -= vramop.vramwait; |
|
| return(mem[address + VRAM_STEP]); |
|
| } |
|
| |
|
| static REG8 MEMCALL grcg_tcr0(UINT32 address) { |
|
| |
|
| const BYTE *vram; |
|
| REG8 ret; |
|
| |
|
| CPU_REMCLOCK -= vramop.grcgwait; |
|
| vram = mem + LOW15(address); |
|
| ret = 0; |
|
| if (!(grcg.modereg & 1)) { |
|
| ret |= vram[VRAM0_B] ^ grcg.tile[0].b[0]; |
|
| } |
|
| if (!(grcg.modereg & 2)) { |
|
| ret |= vram[VRAM0_R] ^ grcg.tile[1].b[0]; |
|
| } |
|
| if (!(grcg.modereg & 4)) { |
|
| ret |= vram[VRAM0_G] ^ grcg.tile[2].b[0]; |
|
| } |
|
| if (!(grcg.modereg & 8)) { |
|
| ret |= vram[VRAM0_E] ^ grcg.tile[3].b[0]; |
|
| } |
|
| return(ret ^ 0xff); |
|
| } |
|
| |
|
| static REG8 MEMCALL grcg_tcr1(UINT32 address) { |
|
| |
|
| const BYTE *vram; |
|
| REG8 ret; |
|
| |
|
| CPU_REMCLOCK -= vramop.grcgwait; |
|
| ret = 0; |
|
| vram = mem + LOW15(address); |
|
| if (!(grcg.modereg & 1)) { |
|
| ret |= vram[VRAM1_B] ^ grcg.tile[0].b[0]; |
|
| } |
|
| if (!(grcg.modereg & 2)) { |
|
| ret |= vram[VRAM1_R] ^ grcg.tile[1].b[0]; |
|
| } |
|
| if (!(grcg.modereg & 4)) { |
|
| ret |= vram[VRAM1_G] ^ grcg.tile[2].b[0]; |
|
| } |
|
| if (!(grcg.modereg & 8)) { |
|
| ret |= vram[VRAM1_E] ^ grcg.tile[3].b[0]; |
|
| } |
|
| return(ret ^ 0xff); |
|
| } |
} |
| |
|
| static REG8 MEMCALL egc_rd(UINT32 address) { |
|
| |
|
| return(egc_read(address)); |
// ---- memory 000000-0ffffff + 64KB |
| } |
|
| |
|
| static REG8 MEMCALL emmc_rd(UINT32 address) { |
typedef struct { |
| |
MEM8READ rd8[0x22]; |
| return(extmem.pageptr[(address >> 14) & 3][LOW14(address)]); |
MEM8WRITE wr8[0x22]; |
| |
MEM16READ rd16[0x22]; |
| |
MEM16WRITE wr16[0x22]; |
| |
} MEMFN0; |
| |
|
| |
typedef struct { |
| |
MEM8READ brd8; // E8000-F7FFF byte read |
| |
MEM8READ ird8; // F8000-FFFFF byte read |
| |
MEM8WRITE bwr8; // E8000-FFFFF byte write |
| |
MEM16READ brd16; // E8000-F7FFF word read |
| |
MEM16READ ird16; // F8000-FFFFF word read |
| |
MEM16WRITE bwr16; // F8000-FFFFF word write |
| |
} MMAPTBL; |
| |
|
| |
typedef struct { |
| |
MEM8READ rd8; |
| |
MEM8WRITE wr8; |
| |
MEM16READ rd16; |
| |
MEM16WRITE wr16; |
| |
} VACCTBL; |
| |
|
| |
static MEMFN0 memfn0 = { |
| |
{memmain_rd8, memmain_rd8, memmain_rd8, memmain_rd8, // 00 |
| |
memmain_rd8, memmain_rd8, memmain_rd8, memmain_rd8, // 20 |
| |
memmain_rd8, memmain_rd8, memmain_rd8, memmain_rd8, // 40 |
| |
memmain_rd8, memmain_rd8, memmain_rd8, memmain_rd8, // 60 |
| |
memmain_rd8, memmain_rd8, memmain_rd8, memmain_rd8, // 80 |
| |
memtram_rd8, memvram0_rd8, memvram0_rd8, memvram0_rd8, // a0 |
| |
memems_rd8, memems_rd8, memmain_rd8, memmain_rd8, // c0 |
| |
memvram0_rd8, memmain_rd8, memmain_rd8, memf800_rd8, // e0 |
| |
memmain_rd8, memmain_rd8}, |
| |
|
| |
{memmain_wr8, memmain_wr8, memmain_wr8, memmain_wr8, // 00 |
| |
memmain_wr8, memmain_wr8, memmain_wr8, memmain_wr8, // 20 |
| |
memmain_wr8, memmain_wr8, memmain_wr8, memmain_wr8, // 40 |
| |
memmain_wr8, memmain_wr8, memmain_wr8, memmain_wr8, // 60 |
| |
memmain_wr8, memmain_wr8, memmain_wr8, memmain_wr8, // 80 |
| |
memtram_wr8, memvram0_wr8, memvram0_wr8, memvram0_wr8, // a0 |
| |
memems_wr8, memems_wr8, memd000_wr8, memd000_wr8, // c0 |
| |
memvram0_wr8, memnc_wr8, memnc_wr8, memnc_wr8, // e0 |
| |
memmain_wr8, memmain_wr8}, |
| |
|
| |
{memmain_rd16, memmain_rd16, memmain_rd16, memmain_rd16, // 00 |
| |
memmain_rd16, memmain_rd16, memmain_rd16, memmain_rd16, // 20 |
| |
memmain_rd16, memmain_rd16, memmain_rd16, memmain_rd16, // 40 |
| |
memmain_rd16, memmain_rd16, memmain_rd16, memmain_rd16, // 60 |
| |
memmain_rd16, memmain_rd16, memmain_rd16, memmain_rd16, // 80 |
| |
memtram_rd16, memvram0_rd16, memvram0_rd16, memvram0_rd16, // a0 |
| |
memems_rd16, memems_rd16, memmain_rd16, memmain_rd16, // c0 |
| |
memvram0_rd16, memmain_rd16, memmain_rd16, memf800_rd16, // e0 |
| |
memmain_rd16, memmain_rd16}, |
| |
|
| |
{memmain_wr16, memmain_wr16, memmain_wr16, memmain_wr16, // 00 |
| |
memmain_wr16, memmain_wr16, memmain_wr16, memmain_wr16, // 20 |
| |
memmain_wr16, memmain_wr16, memmain_wr16, memmain_wr16, // 40 |
| |
memmain_wr16, memmain_wr16, memmain_wr16, memmain_wr16, // 60 |
| |
memmain_wr16, memmain_wr16, memmain_wr16, memmain_wr16, // 80 |
| |
memtram_wr16, memvram0_wr16, memvram0_wr16, memvram0_wr16, // a0 |
| |
memems_wr16, memems_wr16, memd000_wr16, memd000_wr16, // c0 |
| |
memvram0_wr16, memnc_wr16, memnc_wr16, memnc_wr16, // e0 |
| |
memmain_wr16, memmain_wr16}}; |
| |
|
| |
static const MMAPTBL mmaptbl[2] = { |
| |
{memmain_rd8, memf800_rd8, memnc_wr8, |
| |
memmain_rd16, memf800_rd16, memnc_wr16}, |
| |
{memf800_rd8, memf800_rd8, memepson_wr8, |
| |
memf800_rd16, memf800_rd16, memepson_wr16}}; |
| |
|
| |
static const VACCTBL vacctbl[0x10] = { |
| |
{memvram0_rd8, memvram0_wr8, memvram0_rd16, memvram0_wr16}, // 00 |
| |
{memvram1_rd8, memvram1_wr8, memvram1_rd16, memvram1_wr16}, |
| |
{memvram0_rd8, memvram0_wr8, memvram0_rd16, memvram0_wr16}, |
| |
{memvram1_rd8, memvram1_wr8, memvram1_rd16, memvram1_wr16}, |
| |
{memvram0_rd8, memvram0_wr8, memvram0_rd16, memvram0_wr16}, // 40 |
| |
{memvram1_rd8, memvram1_wr8, memvram1_rd16, memvram1_wr16}, |
| |
{memvram0_rd8, memvram0_wr8, memvram0_rd16, memvram0_wr16}, |
| |
{memvram1_rd8, memvram1_wr8, memvram1_rd16, memvram1_wr16}, |
| |
{memtcr0_rd8, memtdw0_wr8, memtcr0_rd16, memtdw0_wr16}, // 80 |
| |
{memtcr1_rd8, memtdw1_wr8, memtcr1_rd16, memtdw1_wr16}, |
| |
{memegc_rd8, memegc_wr8, memegc_rd16, memegc_wr16}, |
| |
{memegc_rd8, memegc_wr8, memegc_rd16, memegc_wr16}, |
| |
{memvram0_rd8, memrmw0_wr8, memvram0_rd16, memrmw0_wr16}, // c0 |
| |
{memvram1_rd8, memrmw1_wr8, memvram1_rd16, memrmw1_wr16}, |
| |
{memegc_rd8, memegc_wr8, memegc_rd16, memegc_wr16}, |
| |
{memegc_rd8, memegc_wr8, memegc_rd16, memegc_wr16}}; |
| |
|
| |
|
| |
void MEMCALL i286_memorymap(UINT type) { |
| |
|
| |
const MMAPTBL *mm; |
| |
|
| |
mm = mmaptbl + (type & 1); |
| |
|
| |
memfn0.rd8[0xe8000 >> 15] = mm->brd8; |
| |
memfn0.rd8[0xf0000 >> 15] = mm->brd8; |
| |
memfn0.rd8[0xf8000 >> 15] = mm->ird8; |
| |
memfn0.wr8[0xe8000 >> 15] = mm->bwr8; |
| |
memfn0.wr8[0xf0000 >> 15] = mm->bwr8; |
| |
memfn0.wr8[0xf8000 >> 15] = mm->bwr8; |
| |
|
| |
memfn0.rd16[0xe8000 >> 15] = mm->brd16; |
| |
memfn0.rd16[0xf0000 >> 15] = mm->brd16; |
| |
memfn0.rd16[0xf8000 >> 15] = mm->ird16; |
| |
memfn0.wr16[0xe8000 >> 15] = mm->bwr16; |
| |
memfn0.wr16[0xf0000 >> 15] = mm->bwr16; |
| |
memfn0.wr16[0xf8000 >> 15] = mm->bwr16; |
| } |
} |
| |
|
| static REG8 MEMCALL i286_itf(UINT32 address) { |
void MEMCALL i286_vram_dispatch(UINT func) { |
| |
|
| if (CPU_ITFBANK) { |
const VACCTBL *vacc; |
| address = ITF_ADRS + LOW15(address); |
|
| } |
|
| return(mem[address]); |
|
| } |
|
| |
|
| |
#if defined(SUPPORT_PC9821) |
| |
if (!(func & 0x20)) { |
| |
#endif // defined(SUPPORT_PC9821) |
| |
vacc = vacctbl + (func & 0x0f); |
| |
|
| // ---- write word |
memfn0.rd8[0xa8000 >> 15] = vacc->rd8; |
| |
memfn0.rd8[0xb0000 >> 15] = vacc->rd8; |
| |
memfn0.rd8[0xb8000 >> 15] = vacc->rd8; |
| |
memfn0.rd8[0xe0000 >> 15] = vacc->rd8; |
| |
|
| static void MEMCALL i286w_wt(UINT32 address, REG16 value) { |
memfn0.wr8[0xa8000 >> 15] = vacc->wr8; |
| |
memfn0.wr8[0xb0000 >> 15] = vacc->wr8; |
| |
memfn0.wr8[0xb8000 >> 15] = vacc->wr8; |
| |
memfn0.wr8[0xe0000 >> 15] = vacc->wr8; |
| |
|
| BYTE *ptr; |
memfn0.rd16[0xa8000 >> 15] = vacc->rd16; |
| |
memfn0.rd16[0xb0000 >> 15] = vacc->rd16; |
| |
memfn0.rd16[0xb8000 >> 15] = vacc->rd16; |
| |
memfn0.rd16[0xe0000 >> 15] = vacc->rd16; |
| |
|
| ptr = mem + (address & CPU_ADRSMASK); |
memfn0.wr16[0xa8000 >> 15] = vacc->wr16; |
| STOREINTELWORD(ptr, value); |
memfn0.wr16[0xb0000 >> 15] = vacc->wr16; |
| } |
memfn0.wr16[0xb8000 >> 15] = vacc->wr16; |
| |
memfn0.wr16[0xe0000 >> 15] = vacc->wr16; |
| static void MEMCALL tramw_wt(UINT32 address, REG16 value) { |
|
| |
|
| if (address < 0xa1fff) { |
if (!(func & (1 << VOPBIT_ANALOG))) { // digital |
| STOREINTELWORD(mem + address, value); |
memfn0.rd8[0xe0000 >> 15] = memnc_rd8; |
| tramupdate[LOW12(address >> 1)] = 1; |
memfn0.wr8[0xe0000 >> 15] = memnc_wr8; |
| tramupdate[LOW12((address + 1) >> 1)] = 1; |
memfn0.rd16[0xe0000 >> 15] = memnc_rd16; |
| gdcs.textdisp |= 1; |
memfn0.wr16[0xe0000 >> 15] = memnc_wr16; |
| } |
|
| else if (address == 0xa1fff) { |
|
| STOREINTELWORD(mem + address, value); |
|
| tramupdate[0] = 1; |
|
| tramupdate[0xfff] = 1; |
|
| gdcs.textdisp |= 1; |
|
| } |
|
| else if (address < 0xa3fe0) { |
|
| if (address & 1) { |
|
| address++; |
|
| value >>= 8; |
|
| } |
|
| mem[address] = (BYTE)value; |
|
| tramupdate[LOW12(address >> 1)] = 1; |
|
| gdcs.textdisp |= 1; |
|
| } |
|
| else if (address < 0xa3fff) { |
|
| if (address & 1) { |
|
| address++; |
|
| value >>= 8; |
|
| } |
|
| if ((!(address & 2)) || (gdcs.msw_accessable)) { |
|
| mem[address] = (BYTE)value; |
|
| tramupdate[LOW12(address >> 1)] = 1; |
|
| gdcs.textdisp |= 1; |
|
| } |
|
| } |
|
| else if (address < 0xa5000) { |
|
| if (address & 1) { |
|
| value >>= 8; |
|
| } |
|
| if (cgwindow.writable & 1) { |
|
| cgwindow.writable |= 0x80; |
|
| fontrom[cgwindow.high + ((address >> 1) & 0x0f)] = (BYTE)value; |
|
| } |
} |
| } |
#if defined(SUPPORT_PC9821) |
| } |
|
| |
|
| |
|
| #define GRCGW_NON(page) { \ |
|
| CPU_REMCLOCK -= vramop.vramwait; \ |
|
| STOREINTELWORD(mem + address + VRAM_STEP*(page), value); \ |
|
| vramupdate[LOW15(address)] |= (1 << page); \ |
|
| vramupdate[LOW15(address + 1)] |= (1 << page); \ |
|
| gdcs.grphdisp |= (1 << page); \ |
|
| } |
|
| |
|
| #define GRCGW_RMW(page) { \ |
|
| BYTE *vram; \ |
|
| CPU_REMCLOCK -= vramop.grcgwait; \ |
|
| address = LOW15(address); \ |
|
| vramupdate[address] |= (1 << page); \ |
|
| vramupdate[address + 1] |= (1 << page); \ |
|
| gdcs.grphdisp |= (1 << page); \ |
|
| vram = mem + address + (VRAM_STEP * (page)); \ |
|
| if (!(grcg.modereg & 1)) { \ |
|
| BYTE tmp; \ |
|
| tmp = (BYTE)value; \ |
|
| vram[VRAM0_B+0] &= (~tmp); \ |
|
| vram[VRAM0_B+0] |= (tmp & grcg.tile[0].b[0]); \ |
|
| tmp = (BYTE)(value >> 8); \ |
|
| vram[VRAM0_B+1] &= (~tmp); \ |
|
| vram[VRAM0_B+1] |= (tmp & grcg.tile[0].b[0]); \ |
|
| } \ |
|
| if (!(grcg.modereg & 2)) { \ |
|
| BYTE tmp; \ |
|
| tmp = (BYTE)value; \ |
|
| vram[VRAM0_R+0] &= (~tmp); \ |
|
| vram[VRAM0_R+0] |= (tmp & grcg.tile[1].b[0]); \ |
|
| tmp = (BYTE)(value >> 8); \ |
|
| vram[VRAM0_R+1] &= (~tmp); \ |
|
| vram[VRAM0_R+1] |= (tmp & grcg.tile[1].b[0]); \ |
|
| } \ |
|
| if (!(grcg.modereg & 4)) { \ |
|
| BYTE tmp; \ |
|
| tmp = (BYTE)value; \ |
|
| vram[VRAM0_G+0] &= (~tmp); \ |
|
| vram[VRAM0_G+0] |= (tmp & grcg.tile[2].b[0]); \ |
|
| tmp = (BYTE)(value >> 8); \ |
|
| vram[VRAM0_G+1] &= (~tmp); \ |
|
| vram[VRAM0_G+1] |= (tmp & grcg.tile[2].b[0]); \ |
|
| } \ |
|
| if (!(grcg.modereg & 8)) { \ |
|
| BYTE tmp; \ |
|
| tmp = (BYTE)value; \ |
|
| vram[VRAM0_E+0] &= (~tmp); \ |
|
| vram[VRAM0_E+0] |= (tmp & grcg.tile[3].b[0]); \ |
|
| tmp = (BYTE)(value >> 8); \ |
|
| vram[VRAM0_E+1] &= (~tmp); \ |
|
| vram[VRAM0_E+1] |= (tmp & grcg.tile[3].b[0]); \ |
|
| } \ |
|
| } |
|
| |
|
| #define GRCGW_TDW(page) { \ |
|
| BYTE *vram; \ |
|
| CPU_REMCLOCK -= vramop.grcgwait; \ |
|
| address = LOW15(address); \ |
|
| vramupdate[address] |= (1 << page); \ |
|
| vramupdate[address + 1] |= (1 << page); \ |
|
| gdcs.grphdisp |= (1 << page); \ |
|
| vram = mem + address + (VRAM_STEP * (page)); \ |
|
| if (!(grcg.modereg & 1)) { \ |
|
| vram[VRAM0_B+0] = grcg.tile[0].b[0]; \ |
|
| vram[VRAM0_B+1] = grcg.tile[0].b[0]; \ |
|
| } \ |
|
| if (!(grcg.modereg & 2)) { \ |
|
| vram[VRAM0_R+0] = grcg.tile[1].b[0]; \ |
|
| vram[VRAM0_R+1] = grcg.tile[1].b[0]; \ |
|
| } \ |
|
| if (!(grcg.modereg & 4)) { \ |
|
| vram[VRAM0_G+0] = grcg.tile[2].b[0]; \ |
|
| vram[VRAM0_G+1] = grcg.tile[2].b[0]; \ |
|
| } \ |
|
| if (!(grcg.modereg & 8)) { \ |
|
| vram[VRAM0_E+0] = grcg.tile[3].b[0]; \ |
|
| vram[VRAM0_E+1] = grcg.tile[3].b[0]; \ |
|
| } \ |
|
| (void)value; \ |
|
| } |
|
| |
|
| static void MEMCALL vramw_w0(UINT32 address, REG16 value) GRCGW_NON(0) |
|
| static void MEMCALL vramw_w1(UINT32 address, REG16 value) GRCGW_NON(1) |
|
| static void MEMCALL grcgw_rmw0(UINT32 address, REG16 value) GRCGW_RMW(0) |
|
| static void MEMCALL grcgw_rmw1(UINT32 address, REG16 value) GRCGW_RMW(1) |
|
| static void MEMCALL grcgw_tdw0(UINT32 address, REG16 value) GRCGW_TDW(0) |
|
| static void MEMCALL grcgw_tdw1(UINT32 address, REG16 value) GRCGW_TDW(1) |
|
| |
|
| static void MEMCALL egcw_wt(UINT32 address, REG16 value) { |
|
| |
|
| if (!(address & 1)) { |
|
| egc_write_w(address, value); |
|
| } |
} |
| else { |
else { |
| if (!(egc.sft & 0x1000)) { |
memfn0.rd8[0xa8000 >> 15] = memvga0_rd8; |
| egc_write(address, (REG8)value); |
memfn0.rd8[0xb0000 >> 15] = memvga1_rd8; |
| egc_write(address + 1, (REG8)(value >> 8)); |
memfn0.rd8[0xb8000 >> 15] = memnc_rd8; |
| } |
memfn0.rd8[0xe0000 >> 15] = memvgaio_rd8; |
| else { |
|
| egc_write(address + 1, (REG8)(value >> 8)); |
|
| egc_write(address, (REG8)value); |
|
| } |
|
| } |
|
| } |
|
| |
|
| static void MEMCALL emmcw_wt(UINT32 address, REG16 value) { |
memfn0.wr8[0xa8000 >> 15] = memvga0_wr8; |
| |
memfn0.wr8[0xb0000 >> 15] = memvga1_wr8; |
| |
memfn0.wr8[0xb8000 >> 15] = memnc_wr8; |
| |
memfn0.wr8[0xe0000 >> 15] = memvgaio_wr8; |
| |
|
| BYTE *ptr; |
memfn0.rd16[0xa8000 >> 15] = memvga0_rd16; |
| |
memfn0.rd16[0xb0000 >> 15] = memvga1_rd16; |
| |
memfn0.rd16[0xb8000 >> 15] = memnc_rd16; |
| |
memfn0.rd16[0xe0000 >> 15] = memvgaio_rd16; |
| |
|
| if ((address & 0x3fff) != 0x3fff) { |
memfn0.wr16[0xa8000 >> 15] = memvga0_wr16; |
| ptr = extmem.pageptr[(address >> 14) & 3] + LOW14(address); |
memfn0.wr16[0xb0000 >> 15] = memvga1_wr16; |
| STOREINTELWORD(ptr, value); |
memfn0.wr16[0xb8000 >> 15] = memnc_wr16; |
| } |
memfn0.wr16[0xe0000 >> 15] = memvgaio_wr16; |
| else { |
|
| extmem.pageptr[(address >> 14) & 3][0x3fff] = (BYTE)value; |
|
| extmem.pageptr[((address + 1) >> 14) & 3][0] = (BYTE)(value >> 8); |
|
| } |
} |
| |
#endif // defined(SUPPORT_PC9821) |
| } |
} |
| |
|
| static void MEMCALL i286w_wn(UINT32 address, REG16 value) { |
|
| |
|
| (void)address; |
|
| (void)value; |
|
| } |
|
| |
|
| |
// ---- memory f00000-fffffff |
| |
|
| // ---- read word |
typedef struct { |
| |
MEM8READ rd8[8]; |
| |
MEM8WRITE wr8[8]; |
| |
MEM16READ rd16[8]; |
| |
MEM16WRITE wr16[8]; |
| |
} MEMFNF; |
| |
|
| static REG16 MEMCALL i286w_rd(UINT32 address) { |
|
| |
|
| BYTE *ptr; |
static REG8 MEMCALL memsys_rd8(UINT32 address) { |
| |
|
| ptr = mem + (address & CPU_ADRSMASK); |
address -= 0xf00000; |
| return(LOADINTELWORD(ptr)); |
return(memfn0.rd8[address >> 15](address)); |
| } |
} |
| |
|
| static REG16 MEMCALL tramw_rd(UINT32 address) { |
static REG16 MEMCALL memsys_rd16(UINT32 address) { |
| |
|
| CPU_REMCLOCK -= vramop.tramwait; |
address -= 0xf00000; |
| if (address < (0xa4000 - 1)) { |
return(memfn0.rd16[address >> 15](address)); |
| return(LOADINTELWORD(mem + address)); |
|
| } |
|
| else if (address == 0xa3fff) { |
|
| return(mem[address] + (fontrom[cgwindow.low] << 8)); |
|
| } |
|
| else if (address < 0xa4fff) { |
|
| if (address & 1) { |
|
| REG16 ret; |
|
| ret = fontrom[cgwindow.high + ((address >> 1) & 0x0f)]; |
|
| ret += fontrom[cgwindow.low + (((address + 1) >> 1) & 0x0f)] << 8; |
|
| return(ret); |
|
| } |
|
| else { |
|
| REG16 ret; |
|
| ret = fontrom[cgwindow.low + ((address >> 1) & 0x0f)]; |
|
| ret += fontrom[cgwindow.high + ((address >> 1) & 0x0f)] << 8; |
|
| return(ret); |
|
| } |
|
| } |
|
| else if (address == 0xa4fff) { |
|
| return((mem[0xa5000] << 8) | fontrom[cgwindow.high + 15]); |
|
| } |
|
| return(LOADINTELWORD(mem + address)); |
|
| } |
|
| |
|
| static REG16 MEMCALL vramw_r0(UINT32 address) { |
|
| |
|
| CPU_REMCLOCK -= vramop.vramwait; |
|
| return(LOADINTELWORD(mem + address)); |
|
| } |
} |
| |
|
| static REG16 MEMCALL vramw_r1(UINT32 address) { |
static void MEMCALL memsys_wr8(UINT32 address, REG8 value) { |
| |
|
| CPU_REMCLOCK -= vramop.vramwait; |
address -= 0xf00000; |
| return(LOADINTELWORD(mem + address + VRAM_STEP)); |
memfn0.wr8[address >> 15](address, value); |
| } |
} |
| |
|
| static REG16 MEMCALL grcgw_tcr0(UINT32 address) { |
static void MEMCALL memsys_wr16(UINT32 address, REG16 value) { |
| |
|
| BYTE *vram; |
|
| REG16 ret; |
|
| |
|
| CPU_REMCLOCK -= vramop.grcgwait; |
address -= 0xf00000; |
| ret = 0; |
memfn0.wr16[address >> 15](address, value); |
| vram = mem + LOW15(address); |
|
| if (!(grcg.modereg & 1)) { |
|
| ret |= LOADINTELWORD(vram + VRAM0_B) ^ grcg.tile[0].w; |
|
| } |
|
| if (!(grcg.modereg & 2)) { |
|
| ret |= LOADINTELWORD(vram + VRAM0_R) ^ grcg.tile[1].w; |
|
| } |
|
| if (!(grcg.modereg & 4)) { |
|
| ret |= LOADINTELWORD(vram + VRAM0_G) ^ grcg.tile[2].w; |
|
| } |
|
| if (!(grcg.modereg & 8)) { |
|
| ret |= LOADINTELWORD(vram + VRAM0_E) ^ grcg.tile[3].w; |
|
| } |
|
| return((UINT16)~ret); |
|
| } |
} |
| |
|
| static REG16 MEMCALL grcgw_tcr1(UINT32 address) { |
#if defined(SUPPORT_PC9821) |
| |
static const MEMFNF memfnf = { |
| |
{memvgaf_rd8, memvgaf_rd8, memvgaf_rd8, memvgaf_rd8, |
| |
memnc_rd8, memsys_rd8, memsys_rd8, memsys_rd8}, |
| |
{memvgaf_wr8, memvgaf_wr8, memvgaf_wr8, memvgaf_wr8, |
| |
memnc_wr8, memsys_wr8, memsys_wr8, memsys_wr8}, |
| |
|
| BYTE *vram; |
{memvgaf_rd16, memvgaf_rd16, memvgaf_rd16, memvgaf_rd16, |
| REG16 ret; |
memnc_rd16, memsys_rd16, memsys_rd16, memsys_rd16}, |
| |
{memvgaf_wr16, memvgaf_wr16, memvgaf_wr16, memvgaf_wr16, |
| |
memnc_wr16, memsys_wr16, memsys_wr16, memsys_wr16}}; |
| |
#else |
| |
static const MEMFNF memfnf = { |
| |
{memnc_rd8, memnc_rd8, memnc_rd8, memnc_rd8, |
| |
memnc_rd8, memsys_rd8, memsys_rd8, memsys_rd8}, |
| |
{memnc_wr8, memnc_wr8, memnc_wr8, memnc_wr8, |
| |
memnc_wr8, memsys_wr8, memsys_wr8, memsys_wr8}, |
| |
|
| |
{memnc_rd16, memnc_rd16, memnc_rd16, memnc_rd16, |
| |
memnc_rd16, memsys_rd16, memsys_rd16, memsys_rd16}, |
| |
{memnc_wr16, memnc_wr16, memnc_wr16, memnc_wr16, |
| |
memnc_wr16, memsys_wr16, memsys_wr16, memsys_wr16}}; |
| |
#endif |
| |
|
| CPU_REMCLOCK -= vramop.grcgwait; |
|
| ret = 0; |
|
| vram = mem + LOW15(address); |
|
| if (!(grcg.modereg & 1)) { |
|
| ret |= LOADINTELWORD(vram + VRAM1_B) ^ grcg.tile[0].w; |
|
| } |
|
| if (!(grcg.modereg & 2)) { |
|
| ret |= LOADINTELWORD(vram + VRAM1_R) ^ grcg.tile[1].w; |
|
| } |
|
| if (!(grcg.modereg & 4)) { |
|
| ret |= LOADINTELWORD(vram + VRAM1_G) ^ grcg.tile[2].w; |
|
| } |
|
| if (!(grcg.modereg & 8)) { |
|
| ret |= LOADINTELWORD(vram + VRAM1_E) ^ grcg.tile[3].w; |
|
| } |
|
| return((UINT16)(~ret)); |
|
| } |
|
| |
|
| static REG16 MEMCALL egcw_rd(UINT32 address) { |
// ---- |
| |
|
| REG16 ret; |
REG8 MEMCALL i286_memoryread(UINT32 address) { |
| |
|
| if (!(address & 1)) { |
if (address < I286_MEMREADMAX) { |
| return(egc_read_w(address)); |
return(mem[address]); |
| } |
} |
| else { |
else { |
| if (!(egc.sft & 0x1000)) { |
address = address & CPU_ADRSMASK; |
| ret = egc_read(address); |
if (address < USE_HIMEM) { |
| ret += egc_read(address + 1) << 8; |
return(memfn0.rd8[address >> 15](address)); |
| return(ret); |
|
| } |
} |
| else { |
else if (address < CPU_EXTLIMIT16) { |
| ret = egc_read(address + 1) << 8; |
return(CPU_EXTMEMBASE[address]); |
| ret += egc_read(address); |
|
| return(ret); |
|
| } |
} |
| } |
else if (address < 0x00f00000) { |
| } |
return(0xff); |
| |
} |
| static REG16 MEMCALL emmcw_rd(UINT32 address) { |
else if (address < 0x01000000) { |
| |
return(memfnf.rd8[(address >> 17) & 7](address)); |
| const BYTE *ptr; |
|
| REG16 ret; |
|
| |
|
| if ((address & 0x3fff) != 0x3fff) { |
|
| ptr = extmem.pageptr[(address >> 14) & 3] + LOW14(address); |
|
| return(LOADINTELWORD(ptr)); |
|
| } |
|
| else { |
|
| ret = extmem.pageptr[(address >> 14) & 3][0x3fff]; |
|
| ret += extmem.pageptr[((address + 1) >> 14) & 3][0] << 8; |
|
| return(ret); |
|
| } |
|
| } |
|
| |
|
| static REG16 MEMCALL i286w_itf(UINT32 address) { |
|
| |
|
| if (CPU_ITFBANK) { |
|
| address = ITF_ADRS + LOW15(address); |
|
| } |
|
| return(LOADINTELWORD(mem + address)); |
|
| } |
|
| |
|
| |
|
| // ---- table |
|
| |
|
| typedef void (MEMCALL * MEM8WRITE)(UINT32 address, REG8 value); |
|
| typedef REG8 (MEMCALL * MEM8READ)(UINT32 address); |
|
| typedef void (MEMCALL * MEM16WRITE)(UINT32 address, REG16 value); |
|
| typedef REG16 (MEMCALL * MEM16READ)(UINT32 address); |
|
| |
|
| static MEM8WRITE memory_write[] = { |
|
| i286_wt, i286_wt, i286_wt, i286_wt, // 00 |
|
| i286_wt, i286_wt, i286_wt, i286_wt, // 20 |
|
| i286_wt, i286_wt, i286_wt, i286_wt, // 40 |
|
| i286_wt, i286_wt, i286_wt, i286_wt, // 60 |
|
| i286_wt, i286_wt, i286_wt, i286_wt, // 80 |
|
| tram_wt, vram_w0, vram_w0, vram_w0, // a0 |
|
| emmc_wt, emmc_wt, i286_wn, i286_wn, // c0 |
|
| vram_w0, i286_wn, i286_wn, i286_wn}; // e0 |
|
| |
|
| static MEM8READ memory_read[] = { |
|
| i286_rd, i286_rd, i286_rd, i286_rd, // 00 |
|
| i286_rd, i286_rd, i286_rd, i286_rd, // 20 |
|
| i286_rd, i286_rd, i286_rd, i286_rd, // 40 |
|
| i286_rd, i286_rd, i286_rd, i286_rd, // 60 |
|
| i286_rd, i286_rd, i286_rd, i286_rd, // 80 |
|
| tram_rd, vram_r0, vram_r0, vram_r0, // a0 |
|
| emmc_rd, emmc_rd, i286_rd, i286_rd, // c0 |
|
| vram_r0, i286_rd, i286_rd, i286_itf}; // f0 |
|
| |
|
| static MEM16WRITE memword_write[] = { |
|
| i286w_wt, i286w_wt, i286w_wt, i286w_wt, // 00 |
|
| i286w_wt, i286w_wt, i286w_wt, i286w_wt, // 20 |
|
| i286w_wt, i286w_wt, i286w_wt, i286w_wt, // 40 |
|
| i286w_wt, i286w_wt, i286w_wt, i286w_wt, // 60 |
|
| i286w_wt, i286w_wt, i286w_wt, i286w_wt, // 80 |
|
| tramw_wt, vramw_w0, vramw_w0, vramw_w0, // a0 |
|
| emmcw_wt, emmcw_wt, i286w_wn, i286w_wn, // c0 |
|
| vramw_w0, i286w_wn, i286w_wn, i286w_wn}; // e0 |
|
| |
|
| static MEM16READ memword_read[] = { |
|
| i286w_rd, i286w_rd, i286w_rd, i286w_rd, // 00 |
|
| i286w_rd, i286w_rd, i286w_rd, i286w_rd, // 20 |
|
| i286w_rd, i286w_rd, i286w_rd, i286w_rd, // 40 |
|
| i286w_rd, i286w_rd, i286w_rd, i286w_rd, // 60 |
|
| i286w_rd, i286w_rd, i286w_rd, i286w_rd, // 80 |
|
| tramw_rd, vramw_r0, vramw_r0, vramw_r0, // a0 |
|
| emmcw_rd, emmcw_rd, i286w_rd, i286w_rd, // c0 |
|
| vramw_r0, i286w_rd, i286w_rd, i286w_itf}; // e0 |
|
| |
|
| static const MEM8WRITE vram_write[] = { |
|
| vram_w0, vram_w1, vram_w0, vram_w1, // 00 |
|
| vram_w0, vram_w1, vram_w0, vram_w1, // 40 |
|
| grcg_tdw0, grcg_tdw1, egc_wt, egc_wt, // 80 tdw/tcr |
|
| grcg_rmw0, grcg_rmw1, egc_wt, egc_wt}; // c0 rmw |
|
| |
|
| static const MEM8READ vram_read[] = { |
|
| vram_r0, vram_r1, vram_r0, vram_r1, // 00 |
|
| vram_r0, vram_r1, vram_r0, vram_r1, // 40 |
|
| grcg_tcr0, grcg_tcr1, egc_rd, egc_rd, // 80 tdw/tcr |
|
| vram_r0, vram_r1, egc_rd, egc_rd}; // c0 rmw |
|
| |
|
| static const MEM16WRITE vramw_write[] = { |
|
| vramw_w0, vramw_w1, vramw_w0, vramw_w1, // 00 |
|
| vramw_w0, vramw_w1, vramw_w0, vramw_w1, // 40 |
|
| grcgw_tdw0, grcgw_tdw1, egcw_wt, egcw_wt, // 80 tdw/tcr |
|
| grcgw_rmw0, grcgw_rmw1, egcw_wt, egcw_wt}; // c0 rmw |
|
| |
|
| static const MEM16READ vramw_read[] = { |
|
| vramw_r0, vramw_r1, vramw_r0, vramw_r1, // 00 |
|
| vramw_r0, vramw_r1, vramw_r0, vramw_r1, // 40 |
|
| grcgw_tcr0, grcgw_tcr1, egcw_rd, egcw_rd, // 80 tdw/tcr |
|
| vramw_r0, vramw_r1, egcw_rd, egcw_rd}; // c0 rmw |
|
| |
|
| |
|
| static REG8 MEMCALL i286_nonram_r(UINT32 address) { |
|
| |
|
| (void)address; |
|
| return(0xff); |
|
| } |
|
| |
|
| static REG16 MEMCALL i286_nonram_rw(UINT32 address) { |
|
| |
|
| (void)address; |
|
| return(0xffff); |
|
| } |
|
| |
|
| void MEMCALL i286_vram_dispatch(UINT func) { |
|
| |
|
| UINT proc; |
|
| |
|
| proc = func & 0x0f; |
|
| memory_write[0xa8000 >> 15] = vram_write[proc]; |
|
| memory_write[0xb0000 >> 15] = vram_write[proc]; |
|
| memory_write[0xb8000 >> 15] = vram_write[proc]; |
|
| memory_write[0xe0000 >> 15] = vram_write[proc]; |
|
| |
|
| memory_read[0xa8000 >> 15] = vram_read[proc]; |
|
| memory_read[0xb0000 >> 15] = vram_read[proc]; |
|
| memory_read[0xb8000 >> 15] = vram_read[proc]; |
|
| memory_read[0xe0000 >> 15] = vram_read[proc]; |
|
| |
|
| memword_write[0xa8000 >> 15] = vramw_write[proc]; |
|
| memword_write[0xb0000 >> 15] = vramw_write[proc]; |
|
| memword_write[0xb8000 >> 15] = vramw_write[proc]; |
|
| memword_write[0xe0000 >> 15] = vramw_write[proc]; |
|
| |
|
| memword_read[0xa8000 >> 15] = vramw_read[proc]; |
|
| memword_read[0xb0000 >> 15] = vramw_read[proc]; |
|
| memword_read[0xb8000 >> 15] = vramw_read[proc]; |
|
| memword_read[0xe0000 >> 15] = vramw_read[proc]; |
|
| |
|
| if (!(func & 0x10)) { // degital |
|
| memory_write[0xe0000 >> 15] = i286_wn; |
|
| memword_write[0xe0000 >> 15] = i286w_wn; |
|
| memory_read[0xe0000 >> 15] = i286_nonram_r; |
|
| memword_read[0xe0000 >> 15] = i286_nonram_rw; |
|
| } |
|
| } |
|
| |
|
| #if defined(MEMORY_DEBUG) |
|
| static REG8 MEMCALL _i286_memoryread(UINT32 address) { |
|
| |
|
| if (address < I286_MEMREADMAX) { |
|
| return(mem[address]); |
|
| } |
|
| #if defined(USE_HIMEM) |
|
| else if (address >= 0x10fff0) { |
|
| address -= 0x100000; |
|
| if (address < CPU_EXTMEMSIZE) { |
|
| return(CPU_EXTMEM[address]); |
|
| } |
} |
| |
#if defined(CPU_EXTLIMIT) |
| |
else if (address < CPU_EXTLIMIT) { |
| |
return(CPU_EXTMEMBASE[address]); |
| |
} |
| |
#endif // defined(CPU_EXTLIMIT) |
| |
#if defined(SUPPORT_PC9821) |
| |
else if ((address >= 0xfff00000) && (address < 0xfff80000)) { |
| |
return(memvgaf_rd8(address)); |
| |
} |
| |
#endif // defined(SUPPORT_PC9821) |
| else { |
else { |
| |
// TRACEOUT(("out of mem (read8): %x", address)); |
| return(0xff); |
return(0xff); |
| } |
} |
| } |
} |
| #endif |
|
| else { |
|
| return(memory_read[(address >> 15) & 0x1f](address)); |
|
| } |
|
| } |
} |
| |
|
| static REG16 MEMCALL _i286_memoryread_w(UINT32 address) { |
REG16 MEMCALL i286_memoryread_w(UINT32 address) { |
| |
|
| REG16 ret; |
REG16 ret; |
| |
|
| if (address < (I286_MEMREADMAX - 1)) { |
if (address < (I286_MEMREADMAX - 1)) { |
| return(LOADINTELWORD(mem + address)); |
return(LOADINTELWORD(mem + address)); |
| } |
} |
| #if defined(USE_HIMEM) |
else if ((address + 1) & 0x7fff) { // non 32kb boundary |
| else if (address >= (0x10fff0 - 1)) { |
address = address & CPU_ADRSMASK; |
| address -= 0x100000; |
if (address < USE_HIMEM) { |
| if (address == (0x00fff0 - 1)) { |
return(memfn0.rd16[address >> 15](address)); |
| ret = mem[0x100000 + address]; |
} |
| } |
else if (address < CPU_EXTLIMIT16) { |
| else if (address < CPU_EXTMEMSIZE) { |
return(LOADINTELWORD(CPU_EXTMEMBASE + address)); |
| ret = CPU_EXTMEM[address]; |
} |
| |
else if (address < 0x00f00000) { |
| |
return(0xffff); |
| |
} |
| |
else if (address < 0x01000000) { |
| |
return(memfnf.rd16[(address >> 17) & 7](address)); |
| |
} |
| |
#if defined(CPU_EXTLIMIT) |
| |
else if (address < CPU_EXTLIMIT) { |
| |
return(LOADINTELWORD(CPU_EXTMEMBASE + address)); |
| |
} |
| |
#endif // defined(CPU_EXTLIMIT) |
| |
#if defined(SUPPORT_PC9821) |
| |
else if ((address >= 0xfff00000) && (address < 0xfff80000)) { |
| |
return(memvgaf_rd16(address)); |
| } |
} |
| |
#endif // defined(SUPPORT_PC9821) |
| else { |
else { |
| ret = 0xff; |
// TRACEOUT(("out of mem (read16): %x", address)); |
| |
return(0xffff); |
| } |
} |
| address++; |
|
| if (address < CPU_EXTMEMSIZE) { |
|
| ret += CPU_EXTMEM[address] << 8; |
|
| } |
|
| else { |
|
| ret += 0xff00; |
|
| } |
|
| return(ret); |
|
| } |
|
| #endif |
|
| else if ((address & 0x7fff) != 0x7fff) { |
|
| return(memword_read[(address >> 15) & 0x1f](address)); |
|
| } |
} |
| else { |
else { |
| ret = memory_read[(address >> 15) & 0x1f](address); |
ret = i286_memoryread(address + 0); |
| address++; |
ret += (REG16)(i286_memoryread(address + 1) << 8); |
| ret += memory_read[(address >> 15) & 0x1f](address) << 8; |
|
| return(ret); |
return(ret); |
| } |
} |
| } |
} |
| |
|
| REG8 MEMCALL i286_memoryread(UINT32 address) { |
UINT32 MEMCALL i286_memoryread_d(UINT32 address) { |
| |
|
| REG8 r; |
|
| |
|
| r = _i286_memoryread(address); |
UINT32 pos; |
| if (r & 0xffffff00) { |
UINT32 ret; |
| TRACEOUT(("error i286_memoryread %x %x", address, r)); |
|
| } |
|
| return(r); |
|
| } |
|
| |
|
| REG16 MEMCALL i286_memoryread_w(UINT32 address) { |
|
| |
|
| REG16 r; |
|
| |
|
| r = _i286_memoryread_w(address); |
|
| if (r & 0xffff0000) { |
|
| TRACEOUT(("error i286_memoryread_w %x %x", address, r)); |
|
| } |
|
| return(r); |
|
| } |
|
| #else |
|
| REG8 MEMCALL i286_memoryread(UINT32 address) { |
|
| |
|
| if (address < I286_MEMREADMAX) { |
if (address < (I286_MEMREADMAX - 3)) { |
| return(mem[address]); |
return(LOADINTELDWORD(mem + address)); |
| } |
} |
| #if defined(USE_HIMEM) |
else if (address >= USE_HIMEM) { |
| else if (address >= 0x10fff0) { |
pos = address & CPU_ADRSMASK; |
| address -= 0x100000; |
if ((pos >= USE_HIMEM) && ((pos + 3) < CPU_EXTLIMIT16)) { |
| if (address < CPU_EXTMEMSIZE) { |
return(LOADINTELDWORD(CPU_EXTMEMBASE + pos)); |
| return(CPU_EXTMEM[address]); |
|
| } |
|
| else { |
|
| return(0xff); |
|
| } |
} |
| } |
} |
| #endif |
if (!(address & 1)) { |
| |
ret = i286_memoryread_w(address + 0); |
| |
ret += (UINT32)i286_memoryread_w(address + 2) << 16; |
| |
} |
| else { |
else { |
| return(memory_read[(address >> 15) & 0x1f](address)); |
ret = i286_memoryread(address + 0); |
| |
ret += (UINT32)i286_memoryread_w(address + 1) << 8; |
| |
ret += (UINT32)i286_memoryread(address + 3) << 24; |
| } |
} |
| |
return(ret); |
| } |
} |
| |
|
| REG16 MEMCALL i286_memoryread_w(UINT32 address) { |
void MEMCALL i286_memorywrite(UINT32 address, REG8 value) { |
| |
|
| REG16 ret; |
|
| |
|
| if (address < (I286_MEMREADMAX - 1)) { |
if (address < I286_MEMWRITEMAX) { |
| return(LOADINTELWORD(mem + address)); |
mem[address] = (UINT8)value; |
| } |
} |
| #if defined(USE_HIMEM) |
else { |
| else if (address >= (0x10fff0 - 1)) { |
address = address & CPU_ADRSMASK; |
| address -= 0x100000; |
if (address < USE_HIMEM) { |
| if (address == (0x00fff0 - 1)) { |
memfn0.wr8[address >> 15](address, value); |
| ret = mem[0x100000 + address]; |
|
| } |
} |
| else if (address < CPU_EXTMEMSIZE) { |
else if (address < CPU_EXTLIMIT16) { |
| ret = CPU_EXTMEM[address]; |
CPU_EXTMEMBASE[address] = (UINT8)value; |
| } |
} |
| else { |
else if (address < 0x00f00000) { |
| ret = 0xff; |
} |
| |
else if (address < 0x01000000) { |
| |
memfnf.wr8[(address >> 17) & 7](address, value); |
| |
} |
| |
#if defined(CPU_EXTLIMIT) |
| |
else if (address < CPU_EXTLIMIT) { |
| |
CPU_EXTMEMBASE[address] = (UINT8)value; |
| } |
} |
| address++; |
#endif // defined(CPU_EXTLIMIT) |
| if (address < CPU_EXTMEMSIZE) { |
#if defined(SUPPORT_PC9821) |
| ret += CPU_EXTMEM[address] << 8; |
else if ((address >= 0xfff00000) && (address < 0xfff80000)) { |
| |
memvgaf_wr8(address, value); |
| } |
} |
| |
#endif // defined(SUPPORT_PC9821) |
| else { |
else { |
| ret += 0xff00; |
// TRACEOUT(("out of mem (write8): %x", address)); |
| } |
} |
| return(ret); |
|
| } |
|
| #endif |
|
| else if ((address & 0x7fff) != 0x7fff) { |
|
| return(memword_read[(address >> 15) & 0x1f](address)); |
|
| } |
|
| else { |
|
| ret = memory_read[(address >> 15) & 0x1f](address); |
|
| address++; |
|
| ret += memory_read[(address >> 15) & 0x1f](address) << 8; |
|
| return(ret); |
|
| } |
} |
| } |
} |
| #endif |
|
| |
|
| void MEMCALL i286_memorywrite(UINT32 address, REG8 value) { |
void MEMCALL i286_memorywrite_w(UINT32 address, REG16 value) { |
| |
|
| if (address < I286_MEMWRITEMAX) { |
if (address < (I286_MEMWRITEMAX - 1)) { |
| mem[address] = (BYTE)value; |
STOREINTELWORD(mem + address, value); |
| } |
} |
| #if defined(USE_HIMEM) |
else if ((address + 1) & 0x7fff) { // non 32kb boundary |
| else if (address >= 0x10fff0) { |
address = address & CPU_ADRSMASK; |
| address -= 0x100000; |
if (address < USE_HIMEM) { |
| if (address < CPU_EXTMEMSIZE) { |
memfn0.wr16[address >> 15](address, value); |
| CPU_EXTMEM[address] = (BYTE)value; |
} |
| |
else if (address < CPU_EXTLIMIT16) { |
| |
STOREINTELWORD(CPU_EXTMEMBASE + address, value); |
| |
} |
| |
else if (address < 0x00f00000) { |
| |
} |
| |
else if (address < 0x01000000) { |
| |
memfnf.wr16[(address >> 17) & 7](address, value); |
| |
} |
| |
#if defined(CPU_EXTLIMIT) |
| |
else if (address < CPU_EXTLIMIT) { |
| |
STOREINTELWORD(CPU_EXTMEMBASE + address, value); |
| |
} |
| |
#endif // defined(CPU_EXTLIMIT) |
| |
#if defined(SUPPORT_PC9821) |
| |
else if ((address >= 0xfff00000) && (address < 0xfff80000)) { |
| |
memvgaf_wr16(address, value); |
| |
} |
| |
#endif // defined(SUPPORT_PC9821) |
| |
else { |
| |
// TRACEOUT(("out of mem (write16): %x", address)); |
| } |
} |
| } |
} |
| #endif |
|
| else { |
else { |
| memory_write[(address >> 15) & 0x1f](address, value); |
i286_memorywrite(address + 0, (UINT8)value); |
| |
i286_memorywrite(address + 1, (UINT8)(value >> 8)); |
| } |
} |
| } |
} |
| |
|
| void MEMCALL i286_memorywrite_w(UINT32 address, REG16 value) { |
void MEMCALL i286_memorywrite_d(UINT32 address, UINT32 value) { |
| |
|
| if (address < (I286_MEMWRITEMAX - 1)) { |
UINT32 pos; |
| STOREINTELWORD(mem + address, value); |
|
| |
if (address < (I286_MEMWRITEMAX - 3)) { |
| |
STOREINTELDWORD(mem + address, value); |
| |
return; |
| } |
} |
| #if defined(USE_HIMEM) |
else if (address >= USE_HIMEM) { |
| else if (address >= (0x10fff0 - 1)) { |
pos = address & CPU_ADRSMASK; |
| address -= 0x100000; |
if ((pos >= USE_HIMEM) && ((pos + 3) < CPU_EXTLIMIT16)) { |
| if (address == (0x00fff0 - 1)) { |
STOREINTELDWORD(CPU_EXTMEMBASE + pos, value); |
| mem[address] = (BYTE)value; |
return; |
| } |
|
| else if (address < CPU_EXTMEMSIZE) { |
|
| CPU_EXTMEM[address] = (BYTE)value; |
|
| } |
|
| address++; |
|
| if (address < CPU_EXTMEMSIZE) { |
|
| CPU_EXTMEM[address] = (BYTE)(value >> 8); |
|
| } |
} |
| } |
} |
| #endif |
if (!(address & 1)) { |
| else if ((address & 0x7fff) != 0x7fff) { |
i286_memorywrite_w(address + 0, (UINT16)value); |
| memword_write[(address >> 15) & 0x1f](address, value); |
i286_memorywrite_w(address + 2, (UINT16)(value >> 16)); |
| } |
} |
| else { |
else { |
| memory_write[(address >> 15) & 0x1f](address, (BYTE)value); |
i286_memorywrite(address + 0, (UINT8)value); |
| address++; |
i286_memorywrite_w(address + 1, (UINT16)(value >> 8)); |
| memory_write[(address >> 15) & 0x1f](address, (BYTE)(value >> 8)); |
i286_memorywrite(address + 3, (UINT8)(value >> 24)); |
| } |
} |
| } |
} |
| |
|
| REG8 MEMCALL i286_membyte_read(UINT seg, UINT off) { |
|
| |
// ---- Logical Space (BIOS) |
| |
|
| |
REG8 MEMCALL meml_read8(UINT seg, UINT off) { |
| |
|
| UINT32 address; |
UINT32 address; |
| |
|
| address = (seg << 4) + off; |
address = (seg << 4) + LOW16(off); |
| if (address < I286_MEMREADMAX) { |
if (address < I286_MEMREADMAX) { |
| return(mem[address]); |
return(mem[address]); |
| } |
} |
|
Line 941 REG8 MEMCALL i286_membyte_read(UINT seg,
|
Line 536 REG8 MEMCALL i286_membyte_read(UINT seg,
|
| } |
} |
| } |
} |
| |
|
| REG16 MEMCALL i286_memword_read(UINT seg, UINT off) { |
REG16 MEMCALL meml_read16(UINT seg, UINT off) { |
| |
|
| UINT32 address; |
UINT32 address; |
| |
|
| address = (seg << 4) + off; |
address = (seg << 4) + LOW16(off); |
| if (address < (I286_MEMREADMAX - 1)) { |
if (address < (I286_MEMREADMAX - 1)) { |
| return(LOADINTELWORD(mem + address)); |
return(LOADINTELWORD(mem + address)); |
| } |
} |
|
Line 954 REG16 MEMCALL i286_memword_read(UINT seg
|
Line 549 REG16 MEMCALL i286_memword_read(UINT seg
|
| } |
} |
| } |
} |
| |
|
| void MEMCALL i286_membyte_write(UINT seg, UINT off, REG8 value) { |
void MEMCALL meml_write8(UINT seg, UINT off, REG8 value) { |
| |
|
| UINT32 address; |
UINT32 address; |
| |
|
| address = (seg << 4) + off; |
address = (seg << 4) + LOW16(off); |
| if (address < I286_MEMWRITEMAX) { |
if (address < I286_MEMWRITEMAX) { |
| mem[address] = (BYTE)value; |
mem[address] = (UINT8)value; |
| } |
} |
| else { |
else { |
| i286_memorywrite(address, value); |
i286_memorywrite(address, value); |
| } |
} |
| } |
} |
| |
|
| void MEMCALL i286_memword_write(UINT seg, UINT off, REG16 value) { |
void MEMCALL meml_write16(UINT seg, UINT off, REG16 value) { |
| |
|
| UINT32 address; |
UINT32 address; |
| |
|
| address = (seg << 4) + off; |
address = (seg << 4) + LOW16(off); |
| if (address < (I286_MEMWRITEMAX - 1)) { |
if (address < (I286_MEMWRITEMAX - 1)) { |
| STOREINTELWORD(mem + address, value); |
STOREINTELWORD(mem + address, value); |
| } |
} |
|
Line 980 void MEMCALL i286_memword_write(UINT seg
|
Line 575 void MEMCALL i286_memword_write(UINT seg
|
| } |
} |
| } |
} |
| |
|
| void MEMCALL i286_memstr_read(UINT seg, UINT off, void *dat, UINT leng) { |
void MEMCALL meml_readstr(UINT seg, UINT off, void *dat, UINT leng) { |
| |
|
| BYTE *out; |
UINT8 *out; |
| UINT32 adrs; |
UINT32 adrs; |
| UINT size; |
UINT size; |
| |
|
| out = (BYTE *)dat; |
out = (UINT8 *)dat; |
| adrs = seg << 4; |
adrs = seg << 4; |
| |
off = LOW16(off); |
| if ((I286_MEMREADMAX >= 0x10000) && |
if ((I286_MEMREADMAX >= 0x10000) && |
| (adrs < (I286_MEMREADMAX - 0x10000))) { |
(adrs < (I286_MEMREADMAX - 0x10000))) { |
| if (leng) { |
if (leng) { |
|
Line 1017 void MEMCALL i286_memstr_read(UINT seg,
|
Line 613 void MEMCALL i286_memstr_read(UINT seg,
|
| } |
} |
| } |
} |
| |
|
| void MEMCALL i286_memstr_write(UINT seg, UINT off, |
void MEMCALL meml_writestr(UINT seg, UINT off, const void *dat, UINT leng) { |
| const void *dat, UINT leng) { |
|
| |
|
| BYTE *out; |
UINT8 *out; |
| UINT32 adrs; |
UINT32 adrs; |
| UINT size; |
UINT size; |
| |
|
| out = (BYTE *)dat; |
out = (UINT8 *)dat; |
| adrs = seg << 4; |
adrs = seg << 4; |
| |
off = LOW16(off); |
| if ((I286_MEMWRITEMAX >= 0x10000) && |
if ((I286_MEMWRITEMAX >= 0x10000) && |
| (adrs < (I286_MEMWRITEMAX - 0x10000))) { |
(adrs < (I286_MEMWRITEMAX - 0x10000))) { |
| if (leng) { |
if (leng) { |
|
Line 1055 void MEMCALL i286_memstr_write(UINT seg,
|
Line 651 void MEMCALL i286_memstr_write(UINT seg,
|
| } |
} |
| } |
} |
| |
|
| void MEMCALL i286_memx_read(UINT32 address, void *dat, UINT leng) { |
void MEMCALL meml_read(UINT32 address, void *dat, UINT leng) { |
| |
|
| if ((address + leng) < I286_MEMREADMAX) { |
if ((address + leng) < I286_MEMREADMAX) { |
| CopyMemory(dat, mem + address, leng); |
CopyMemory(dat, mem + address, leng); |
| } |
} |
| else { |
else { |
| BYTE *out = (BYTE *)dat; |
UINT8 *out = (UINT8 *)dat; |
| if (address < I286_MEMREADMAX) { |
if (address < I286_MEMREADMAX) { |
| CopyMemory(out, mem + address, I286_MEMREADMAX - address); |
CopyMemory(out, mem + address, I286_MEMREADMAX - address); |
| out += I286_MEMREADMAX - address; |
out += I286_MEMREADMAX - address; |
|
Line 1074 void MEMCALL i286_memx_read(UINT32 addre
|
Line 670 void MEMCALL i286_memx_read(UINT32 addre
|
| } |
} |
| } |
} |
| |
|
| void MEMCALL i286_memx_write(UINT32 address, const void *dat, UINT leng) { |
void MEMCALL meml_write(UINT32 address, const void *dat, UINT leng) { |
| |
|
| const BYTE *out; |
const UINT8 *out; |
| |
|
| if ((address + leng) < I286_MEMWRITEMAX) { |
if ((address + leng) < I286_MEMWRITEMAX) { |
| CopyMemory(mem + address, dat, leng); |
CopyMemory(mem + address, dat, leng); |
| } |
} |
| else { |
else { |
| out = (BYTE *)dat; |
out = (UINT8 *)dat; |
| if (address < I286_MEMWRITEMAX) { |
if (address < I286_MEMWRITEMAX) { |
| CopyMemory(mem + address, out, I286_MEMWRITEMAX - address); |
CopyMemory(mem + address, out, I286_MEMWRITEMAX - address); |
| out += I286_MEMWRITEMAX - address; |
out += I286_MEMWRITEMAX - address; |
|
Line 1095 const BYTE *out;
|
Line 691 const BYTE *out;
|
| } |
} |
| } |
} |
| |
|
| |
#endif |
| |
|
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